Literature DB >> 29961920

Erythropoietin stimulates fibroblast growth factor 23 (FGF23) in mice and men.

Arezoo Daryadel1,2, Carla Bettoni1,2, Thomas Haider3,4, Pedro H Imenez Silva1,2, Udo Schnitzbauer1,2, Eva Maria Pastor-Arroyo1,2, Roland H Wenger1,2,4, Max Gassmann3,4, Carsten A Wagner5,6,7.   

Abstract

Fibroblast growth factor 23 (FGF23) is a major endocrine regulator of phosphate and 1,25 (OH)2 vitamin D3 metabolism and is mainly produced by osteocytes. Its production is upregulated by a variety of factors including 1,25 (OH)2 vitamin D3, high dietary phosphate intake, and parathyroid hormone (PTH). Recently, iron deficiency and hypoxia have been suggested as additional regulators of FGF23 and a role of erythropoietin (EPO) was shown. However, the regulation of FGF23 by EPO and the impact on phosphate and 1,25(OH)2 vitamin D3 are not completely understood. Here, we demonstrate that acute administration of recombinant human EPO (rhEPO) to healthy humans increases the C-terminal fragment of FGF23 (C-terminal FGF23) but not intact FGF23 (iFGF23). In mice, rhEPO stimulates acutely (24 h) C-terminal FGF23 but iFGF23 only after 4 days without effects on PTH and plasma phosphate. 1,25 (OH)2 D3 levels and αklotho expression in the kidney decrease after 4 days. rhEPO induced FGF23 mRNA in bone marrow but not in bone, with increased staining of FGF23 in CD71+ erythroid precursors in bone marrow. Chronic elevation of EPO in transgenic mice increases iFGF23. Finally, acute injections of recombinant FGF23 reduced renal EPO mRNA expression. Our data demonstrate stimulation of FGF23 levels in mice which impacts mostly on 1,25 (OH)2 vitamin D3 levels and metabolism. In humans, EPO is mostly associated with the C-terminal fragment of FGF23; in mice, EPO has a time-dependent effect on both FGF23 forms. EPO and FGF23 may form a feedback loop controlling and linking erythropoiesis and mineral metabolism.

Entities:  

Keywords:  Bone; Erythropoietin; FGF23; Kidney; Mineral metabolism; Vitamin D3

Mesh:

Substances:

Year:  2018        PMID: 29961920     DOI: 10.1007/s00424-018-2171-7

Source DB:  PubMed          Journal:  Pflugers Arch        ISSN: 0031-6768            Impact factor:   3.657


  36 in total

Review 1.  Fibroblast growth factor 23 and Klotho: physiology and pathophysiology of an endocrine network of mineral metabolism.

Authors:  Ming Chang Hu; Kazuhiro Shiizaki; Makoto Kuro-o; Orson W Moe
Journal:  Annu Rev Physiol       Date:  2013       Impact factor: 19.318

2.  Fibroblast Growth Factor 23 and Anemia in the Chronic Renal Insufficiency Cohort Study.

Authors:  Rupal Mehta; Xuan Cai; Alexander Hodakowski; Jungwha Lee; Mary Leonard; Ana Ricardo; Jing Chen; Lee Hamm; James Sondheimer; Mirela Dobre; Valentin David; Wei Yang; Alan Go; John W Kusek; Harold Feldman; Myles Wolf; Tamara Isakova
Journal:  Clin J Am Soc Nephrol       Date:  2017-08-07       Impact factor: 8.237

3.  Expression of Fgf23 in activated dendritic cells and macrophages in response to immunological stimuli in mice.

Authors:  Yuki Masuda; Hiroya Ohta; Yumiko Morita; Yoshiaki Nakayama; Ayumi Miyake; Nobuyuki Itoh; Morichika Konishi
Journal:  Biol Pharm Bull       Date:  2015-02-26       Impact factor: 2.233

4.  Erythropoietin's inhibiting impact on hepcidin expression occurs indirectly.

Authors:  Elena Gammella; Victor Diaz; Stefania Recalcati; Paolo Buratti; Michele Samaja; Soumyadeep Dey; Constance Tom Noguchi; Max Gassmann; Gaetano Cairo
Journal:  Am J Physiol Regul Integr Comp Physiol       Date:  2014-12-17       Impact factor: 3.619

5.  Post-transcriptional regulation of erythropoietin mRNA stability by erythropoietin mRNA-binding protein.

Authors:  E C McGary; I J Rondon; B S Beckman
Journal:  J Biol Chem       Date:  1997-03-28       Impact factor: 5.157

6.  Neonatal iron deficiency causes abnormal phosphate metabolism by elevating FGF23 in normal and ADHR mice.

Authors:  Erica L Clinkenbeard; Emily G Farrow; Lelia J Summers; Taryn A Cass; Jessica L Roberts; Christine A Bayt; Tim Lahm; Marjorie Albrecht; Matthew R Allen; Munro Peacock; Kenneth E White
Journal:  J Bone Miner Res       Date:  2014-02       Impact factor: 6.741

7.  Erythropoietin mRNA levels are governed by both the rate of gene transcription and posttranscriptional events.

Authors:  M A Goldberg; C C Gaut; H F Bunn
Journal:  Blood       Date:  1991-01-15       Impact factor: 22.113

Review 8.  Fibroblast growth factor 23: state of the field and future directions.

Authors:  Nisan Bhattacharyya; William H Chong; Rachel I Gafni; Michael T Collins
Journal:  Trends Endocrinol Metab       Date:  2012-08-24       Impact factor: 12.015

9.  Effects of iron deficiency anemia and its treatment on fibroblast growth factor 23 and phosphate homeostasis in women.

Authors:  Myles Wolf; Todd A Koch; David B Bregman
Journal:  J Bone Miner Res       Date:  2013-08       Impact factor: 6.741

10.  Fibroblast growth factor 23 enhances renal klotho abundance.

Authors:  Tsuneo Takenaka; Yusuke Watanabe; Tsutomu Inoue; Takashi Miyazaki; Hiromichi Suzuki
Journal:  Pflugers Arch       Date:  2013-03-07       Impact factor: 3.657
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  28 in total

Review 1.  Tumor-Induced Osteomalacia.

Authors:  Pablo Florenzano; Iris R Hartley; Macarena Jimenez; Kelly Roszko; Rachel I Gafni; Michael T Collins
Journal:  Calcif Tissue Int       Date:  2020-06-05       Impact factor: 4.333

Review 2.  Crosstalk between fibroblast growth factor 23, iron, erythropoietin, and inflammation in kidney disease.

Authors:  Jodie L Babitt; Despina Sitara
Journal:  Curr Opin Nephrol Hypertens       Date:  2019-07       Impact factor: 2.894

3.  The HIF-PHI BAY 85-3934 (Molidustat) Improves Anemia and Is Associated With Reduced Levels of Circulating FGF23 in a CKD Mouse Model.

Authors:  Megan L Noonan; Pu Ni; Rafiou Agoro; Spencer A Sacks; Elizabeth A Swallow; Jonathan A Wheeler; Erica L Clinkenbeard; Maegan L Capitano; Matthew Prideaux; Gerald J Atkins; William R Thompson; Matthew R Allen; Hal E Broxmeyer; Kenneth E White
Journal:  J Bone Miner Res       Date:  2021-03-10       Impact factor: 6.741

Review 4.  Non-renal-Related Mechanisms of FGF23 Pathophysiology.

Authors:  Mark R Hanudel; Marciana Laster; Isidro B Salusky
Journal:  Curr Osteoporos Rep       Date:  2018-12       Impact factor: 5.096

Review 5.  Fibroblast growth factor 23 and α-Klotho co-dependent and independent functions.

Authors:  L Darryl Quarles
Journal:  Curr Opin Nephrol Hypertens       Date:  2019-01       Impact factor: 2.894

6.  Peroxisome proliferator-activated receptor α (PPARα)-dependent regulation of fibroblast growth factor 23 (FGF23).

Authors:  Franz Ewendt; Frank Hirche; Martina Feger; Michael Föller
Journal:  Pflugers Arch       Date:  2020-03-18       Impact factor: 3.657

7.  Extra-Large Gα Protein (XLαs) Deficiency Causes Severe Adenine-Induced Renal Injury with Massive FGF23 Elevation.

Authors:  Julia Matthias; Qiuxia Cui; Lauren T Shumate; Antonius Plagge; Qing He; Murat Bastepe
Journal:  Endocrinology       Date:  2020-01-01       Impact factor: 4.736

8.  Regulation of Fibroblast Growth Factor 23 by Iron, EPO, and HIF.

Authors:  Jonathan A Wheeler; Erica L Clinkenbeard
Journal:  Curr Mol Biol Rep       Date:  2019-01-25

Review 9.  FGF23 at the crossroads of phosphate, iron economy and erythropoiesis.

Authors:  Daniel Edmonston; Myles Wolf
Journal:  Nat Rev Nephrol       Date:  2019-09-13       Impact factor: 28.314

10.  Interplay of erythropoietin, fibroblast growth factor 23, and erythroferrone in patients with hereditary hemolytic anemia.

Authors:  Annelies J van Vuren; Michele F Eisenga; Stephanie van Straaten; Andreas Glenthøj; Carlo A J M Gaillard; Stephan J L Bakker; Martin H de Borst; Richard van Wijk; Eduard J van Beers
Journal:  Blood Adv       Date:  2020-04-28
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